KR20160094919A - Method and Apparatus to Control Wireless Power Transform - Google Patents

Abstract

Provided are a method and an apparatus for controlling wireless power transmission. According to an aspect of the present invention, the method for controlling wireless power transmission includes a step of transmitting a wake-up request signal for waking up a target device, a step of receiving a response message from the target device activated by the wake-up request signal, a step of setting demand power based on the response message, and a step of transmitting resonance power to the target device, based on the demand power. So, the power transmission can be stably carried out.

Description

TECHNICAL FIELD [0001] The present invention relates to a wireless power transmission control method and apparatus,

The technical field relates to a wireless power transmission system, for example a resonant power transmission system. More particularly, the present invention relates to a wireless power transmission control apparatus and method.

In recent years, with the development of IT technology, a variety of portable electronic products have been introduced and their spread is increasing. Due to the characteristics of portable electronic products, battery performance of the portable electronic products is becoming an important issue. The ability to transmit data wirelessly in portable electronics as well as in household appliances is provided, but power is provided through the power line.

Recently, wireless power transmission technology capable of supplying power wirelessly has been studied. Due to the characteristics of the radio environment, the distance between the source resonator and the target resonator is likely to vary with time, and the matching conditions of both resonators may also vary. In this specification, a new scheme for increasing the efficiency of wireless transmission in such a variable situation is presented.

In one aspect, a wireless power transfer control method includes transmitting a wake-up request signal for waking up a target device, receiving a response message from a target device activated by the wake-up request signal, Setting a demanded power based on the response message, and transmitting the resonant power to the target device based on the demanded power.

In one aspect, a wireless power transmission control apparatus includes: a communication unit that transmits a wake-up request signal for waking up a target apparatus and receives a response message from a target apparatus activated by the wake-up request; And a source resonator for transmitting the resonant power corresponding to the demanded electric power to the target device.

In another aspect, a wireless power transmission control apparatus includes a target resonator operating at the same resonance frequency as the source resonator, and a control unit for receiving a wake-up request signal from the source apparatus and transmitting a response message to the wake- And a control unit activated by the resonance power included in the wake-up signal and generating the response message. The response message may include information about an identifier (ID) of a target device and necessary power.

By sensing AC and DC power at the source device or sensing received power at the target device, stable power transmission and system operation is possible in the wireless power transmission system.

It is possible to efficiently manage the demand power of the target apparatus and the transmission power of the source apparatus.

It is possible to identify the target device and control the transmission power in consideration of the state of the target device.

1 is a diagram for explaining a wireless power transmission system according to an exemplary embodiment.
2 is a diagram illustrating a wireless power transmission control method according to an exemplary embodiment.
3 shows a response message format according to an exemplary embodiment.
4 shows a configuration of a wireless power transmission control apparatus according to an exemplary embodiment.
5 shows a configuration of an AC generator and a current setting unit according to an exemplary embodiment.
6 shows a configuration of a wireless power transmission control apparatus according to an exemplary embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram for explaining a wireless power transmission system according to an exemplary embodiment.

Referring to FIG. 1, a source device 100 transmits power to at least one target device 110, 120, 130. At this time, the source apparatus 100 may generate resonance power and wirelessly transmit the generated resonance power to at least one target apparatus 110, 120, 130. The source device 100 includes a source resonator that transmits resonant power and at least one of the target devices 110, 120, and 130 includes a target resonator. The source device 100 may be embodied as a module in a portable terminal. At least one of the target devices 110, 120, and 130 may transmit the "Power control data" used for transmission power control to the source device 100, respectively.

2 is a diagram illustrating a wireless power transmission control method according to an exemplary embodiment.

Referring to FIG. 2, in step 210, the source device 100 transmits a wake-up request signal for waking up the target device 110. Here, the target device 110 corresponds to one example, and a plurality of target devices may exist. Here, the wake-up request signal is a signal for searching for a device operating at the same resonance frequency as the source device 100. The wake-up request signal may include power that the target device 110 is used to transition to the receive mode. For example, the wake-up request signal may be transmitted in the form of a 20 MHz continuous wave (CW). At this time, the CW may include enough power that a processor included in the target device 110 can be activated and modulate an arbitrary message.

In step 220, the source device 100 receives a response message from the target device 110 activated by the wake-up request signal. At this time, the response message may include an identifier (ID) of the target device 110 and information on the power required by the target device 110. A specific example of the format of the response message will be described with reference to FIG.

On the other hand, when the source device 100 fails to receive any one of the response messages within a predetermined time, it may periodically transmit a wake-up request signal to detect whether a device exists in the vicinity.

In step 230, the source device 100 sets the demanded power based on the response message, and transmits the resonant power to the target device 110 based on the set demanded power. Step 230 specifically includes demodulating the response message, determining the required current and required voltage of the target device 110 from the demodulated response message, determining the required current and required voltage of the target device 110, And setting the demanded power. That is, the source apparatus 100 sets the demand power based on the "Power control data" received from the target apparatus 110, and can transmit power as much as the demand power to the target apparatus 110. [ In addition, the demanded power can be set in consideration of the number of target devices and the reflected power. That is, the demand power can be set in consideration of a case where there are a plurality of target devices or a case where a plurality of live parts are provided in the target device. In addition, the demanded power may be set in consideration of the reflected power measured at the target device 110, and the reflected power measured at the target device 110. [

In step 240, the target device 110 sends a check message to the source device 100, including an identifier (ID) of the target device and a power receiving status. That is, the target device 110 may transmit its ID to the source device 100 in real time or periodically. The source device 100 can know that the target device 110 still exists by receiving the ID of the target device 110 in real time or periodically. In addition, the target device 110 may inform the source device 100 of the power reception status in real time or periodically. At this time, the power receiving state may include at least one of battery charging state, power on / off state, reflected power amount, coupling information, and power consumption information.

3 shows a response message format according to an exemplary embodiment.

Referring to FIG. 3, the response message may include a preamble 310, an ID 320, setting information 330, and a CRC 340.

The preamble 310 is a bit indicating the start and end of the response message. In addition, the preamble 310 may include a value indicating the start and end of the setting information 330 in the response message.

ID 320 is an identifier of the target device. In addition, the ID 320 may include a type of the target device or product information. The types of target devices can be classified into household appliances, mobile products, and rechargeable batteries.

The setting information 330 includes information necessary for setting the demanded power. That is, the setting information 330 includes information about a rated voltage necessary for operation of the target device, a current required for the target device to operate, a coupling rate, a coupling range, a reflected power amount, . ≪ / RTI > The coupling rate may be defined as a ratio of the amount of power transmitted from the source apparatus 100 to the amount of power received by the target apparatus. The coupling range can be defined as the minimum amount of power required for the target device to operate.

The CRC 340 indicates a parity bit for checking whether a message is erroneous.

Meanwhile, the response message format shown in FIG. 3 may also be used as a format of a check message transmitted in step 240. At this time, the check message may further include information on the system stability state of the target apparatus.

The source apparatus 100 can set the demanded power based on the setting information 330 described in the example of FIG. Therefore, the source apparatus 100 can set the demanded power in consideration of the rated voltage and current required in the target apparatus, and can transmit the set power. Also, the source apparatus 100 may determine the amount of power to be transmitted to the target apparatus in consideration of the coupling rate and the coupling range.

4 shows a configuration of a wireless power transmission control apparatus according to an exemplary embodiment. The example shown in Fig. 4 can be applied to a source device of a wireless power transmission system.

4, the wireless power transmission control apparatus includes a communication unit 410, a control unit 420, and a source resonator 430. The wireless power transmission control apparatus may further include an AC / DC conversion unit 440 and a resonance power generation unit 450. At this time, the resonance power generation unit 450 generates resonance power under the control of the control unit 420, and provides the generated resonance power to the source resonator 430. The resonance power generating unit 450 may include a DC level setting unit 460, an AC generating unit 470, a current setting unit 480, and a resonance power sensing unit 490.

The communication unit 410 transmits a wake-up request signal for waking up the target device. In addition, the communication unit 410 receives a response message from the target device activated by the wake-up request. If there is no error in the response message, the communication unit 410 demodulates the response message, and provides the control unit 420 with information on the ID of the target device and the required power.

The control unit 420 may control the respective configurations included in the resonance power generation unit 450. Further, the controller 420 sets the demanded power based on the modulated response message. For example, the control unit 420 may control the direct current level setting unit 460 in order to set a voltage required by the target device.

The source resonator 430 transmits the resonant power corresponding to the demanded electric power to the target device.

The AC / DC converting unit 440 receives an AC voltage of 85 to 265 volts and converts it into a DC voltage.

The DC level setting unit 460 adjusts the level of the voltage converted to DC by the AC / DC converting unit 440. That is, the direct current level setting unit 460 can set the required voltage corresponding to the demanded electric power. For example, the direct current level setting unit 460 can control the voltage level to a voltage required by the target device under the control of the control unit 420. [

The AC generating unit 470 can generate the AC voltage again from the level adjusted DC voltage. For example, the AC generating unit 470 can generate an AC voltage of 1 MHz or more.

The current setting unit 480 controls the amount of the AC voltage generated by the AC generating unit 470 under the control of the control unit 420. [ That is, the current setting unit 480 can be controlled so that the amount of current required by the target device is generated. Further, the current setting unit 480 can be controlled to generate a constant voltage and current by sensing the amount of current in real time.

The resonance power sensing unit 490 senses the amount of power provided to the source resonator 430 in real time. The control unit 420 controls the resonance power generation unit 450 so that power is transmitted stably by checking the amount of power sensed in real time.

According to the exemplary embodiment shown in Fig. 4, the source device can operate the system stably by sensing the current, voltage, and power amount in real time.

5 shows a configuration of an AC generator and a current setting unit according to an exemplary embodiment.

Referring to FIG. 5, the AC generator 470 may include an RF line 510. At this time, the amount of current can be sensed in real time by measuring the current flowing in the RF line 510 of the current setting unit 480.

The output terminal of the AC generator 470 may include an RF line 520 having a length of? / 4. At this time, if AC coupling is performed at the lambda / 4 point 501 of the RF line 520, the AC voltage and the power amount can be sensed. Here,? Denotes the wavelength of the resonance frequency. At this time, AC coupling at the lambda / 4 point 501 does not affect the main signal, and impedance mismatching can be prevented from occurring. Further, AC coupling at the? / 4 point 501 can be effective for coupling a certain amount of AC voltage. The resonance power sensing unit 490 can ADC-process the coupled AC signal to detect the voltage level.

6 shows a configuration of a wireless power transmission control apparatus according to an exemplary embodiment. The example shown in Fig. 6 can be applied to a target device of a wireless power transmission system.

6, the wireless power transmission control apparatus includes a target resonator 610, a communication unit 620, and a control unit 630. The wireless power transmission control apparatus may further include a received power processing unit 640, a charging unit 650, and a charging state sensing unit 660.

The target resonator 610 operates at the same resonance frequency as the source resonator and receives resonance power.

The communication unit 620 receives a wake up request signal from the source device. In addition, the communication unit 620 transmits a response message to the wake-up request signal to the source device.

The control unit 630 is activated by the resonance power included in the wake-up signal and generates a response message. In addition, the control unit 630 may generate a check message indicating the power consumption state of the target apparatus. In addition, the control unit 630 controls the communication unit 620 to transmit the check message including the identifier (ID) of the target device and the power reception state periodically or non-periodically to the source device.

The received power processing unit 640 processes the power received by the target resonator 610 and provides the DC voltage to the charging unit 650. [ The received power processing unit 640 may include a resonant matching unit 641, a coupling state sensing unit 643, a rectifying unit 645, and a voltage control unit 647.

The resonance matching unit 641 may perform a function of adjusting the resonance frequency of the target resonator 610. [

The coupling state sensing unit 643 can measure the reflected power by coupling the coupling rate and the reflected power between the source resonator and the target resonator 610. And reports the coupling rate and the reflected power measurement value sensed by the coupling state sensing unit 643 to the control unit 630.

The rectification section 645 rectifies the signal received by the target resonator 610 to generate a DC signal.

The voltage control unit 647 adjusts the level of the DC signal rectified by the rectification unit 645. In addition, the voltage controller 647 senses the power supplied to the charger 650, thereby preventing over-power from being supplied.

The charging unit 650 can charge the resonance power and supply power to various loads connected to the target device.

The charging state sensing unit 660 senses the state of charge of the charging unit 650, the completion of charging, and reports the sensing result to the control unit 630.

According to the exemplary embodiment shown in Fig. 6, the target apparatus operates to detect a power receiving state or the like, and to feedback the detected result to the source apparatus, thereby enabling stable system operation.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

Claims (19)

Transmitting wake-up power to the target device;
Receiving a first message from the target device activated by the wakeup power, the first message including information about the power required by the target device;
Setting a demand power based on the first message; And
Transmitting wireless power to the target device based on the demanded power;
/ RTI > The method according to claim 1,
Receiving a second message including a power receiving state of the target device; And
Adjusting the wireless power based on the second message
Further comprising the step of: 3. The method of claim 2,
Wherein the power reception state includes at least one of a battery charging state, a power on / off state, a reflected power amount, coupling information, or power consumption information. 3. The method of claim 2,
Wherein at least one of the first message and the second message further comprises an identifier (ID) of the target device. The method according to claim 1,
Wherein the wake-up power comprises power used by the target device to transition to a receive mode. The method according to claim 1,
The step of setting the demanded electric power includes:
Demodulating the first message;
Determining a required current and a required voltage of the target device from the demodulated first message; And
Setting the demanded power based on a required current and a required voltage of the target device
/ RTI > The method according to claim 1,
Wherein the demanded power is set in consideration of the number of target devices and the reflected power. A power transmission unit for transmitting wakeup power to the target device;
A communication unit for receiving a first message from the target device activated by the wakeup request, the first message including information about power required by the target device; And
A controller for setting demand power based on the first message;
Lt; / RTI >
Wherein the power transmitting unit transmits wireless power to the target device based on the demanded power,
Wireless power transmission control device. 9. The method of claim 8,
Wherein the communication unit further receives a second message including a power reception state of the target apparatus,
And the control unit adjusts the wireless power based on the second message. 9. The method of claim 8,
Wherein the wake-up power comprises power used by the target device to transition to a receive mode. 9. The method of claim 8,
A DC level setting unit for setting a required voltage corresponding to the demanded electric power;
A current setting unit for setting a required current corresponding to the demanded electric power; And
Further comprising a sensor for sensing in real time the wireless power transmitted to the target device. 12. The method of claim 11,
Wherein the sensor senses in real time the wireless power transmitted to the target device using AC power coupled at a lambda / 4 point of the RF line, where lambda is the wavelength of the resonant frequency. Receiving wakeup power from a source device;
Sending a first message to the source device, the first message including information about the power required by the target device; And
Receiving from the source device wireless power according to the set demand power based on the first message;
/ RTI > 14. The method of claim 13,
Further comprising transmitting a second message to the source device, the second message including a power receiving state of the target device,
And the wireless power is adjusted based on the second message. A power receiver for receiving wakeup power from the source device;
A communication unit for transmitting a first message to the source device, the first message including information about power required by the target device; And
Wherein the control unit is activated by the wakeup power,
Lt; / RTI >
And the power receiver receives radio power according to the set demand power from the source device based on the first message. 16. The method of claim 15,
Wherein the communication unit further transmits a second message including a power reception state of the target apparatus to the source apparatus,
And the wireless power is adjusted based on the second message. 17. The method of claim 16,
Wherein at least one of the first message and the second message further comprises an identifier (ID) of the target device,
Wherein the control unit controls the communication unit to periodically or aperiodically transmit the second message. 16. The method of claim 15,
And a coupling state sensing unit for sensing a coupling state between the source resonator and the target resonator. 16. The method of claim 15,
And a charge state sensing unit for sensing a charge state of the target device.

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